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dcp-client

Core libraries for accessing DCP network

  • 3.1.14
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DCP-Client

This is the official client library for DCP, the Distributed Compute Protocol. This library allows client applications to communicate with the Scheduler, Bank, and other parts of a DCP network. This library is redistributable and may be included with other programs under the terms of the MIT license.

Release Notes

Implementation Status

DCP is currently (May 2020) in testing for a limited set of developers under our Early Developer Preview program. If you would like to be part of our First Dev cohort, visit https://dcp.dev/ and sign up!

Note: This document discusses BravoJS, however, BravoJS support is not ready at this time. It will be finished during the Early Developer Preview, in time for our general public release; the documentation is geared toward that release.

Supported Platforms

The DCP-Client code can be made to run in nearly any JavaScript environment which supports ES5 and XMLHttpRequest. Our officially-supported platforms are

  • NodeJS version 10 (LTS)
  • NodeJS version 12 (LTS)
  • BravoJS, latest version
  • Vanilla Web - no module system at all

Other utilities for developers working with DCP can be retrieved via npm, and include:

Installation

The source code for this library is hosted online at https://gitlab.com/Distributed-Compute-Protocol/dcp-client/, and the installation package is available via NPM at https://www.npmjs.com/package/dcp-client.

NodeJS

To use DCP from NodeJS, you need to npm i dcp-client from your project's source directory, which will update your package.json, making this library a dependency of your application.

If you are a Node developer looking to get started quickly, there is a sample project template on GitHub that might interest you at https://github.com/wesgarland/dcp-client.

Vanilla-Web

To use the DCP Client library from a plain vanilla web platform, you must make the contents of the npm package visible to your web application, or use our CDN. Distributed Compute Labs hosts the latest version of the library at https://cdn.distributed.computer/dcp-client/dcp-client.js.

If you are a web developer looking to get started quickly, there are is a sample project on JS Fiddle that might interest you at https://jsfiddle.net/KingsDistributedSystems/58e6up4b/

Self-Hosted Bundle

To host the bundle on your own server, simply acquire the dcp-client package and copy the files dcp-client.js and dcp-client.css into a directory on your web server that your web clients can access. We recommend using the dcp/ directory under your document root.

BravoJS (EDP: not implemented)

To use the DCP Client library with BravoJS, you must make the bundle and the loader visible to your web application.

DCP-Client API

While methods of initializing dcp-client vary somewhat from platform to platform or framework to framework (see below), after initializing, you will have a way to access the key exports of the dcp-client library:

  1. compute - Compute API; compute.run, compute.for, etc.
  2. wallet - Wallet API; used to manipulate data types related to cryptographic authorization, authentication, and access control
  3. worker - Worker API; used for creating embedded Workers on the web or in NodeJS
  4. dcp-config - a configuration object which can override various core options, such as the location of a local HTTP proxy; the initial default is downloaded from protocol://location.of.scheduler/etc/dcp-config
  5. A global symbol, XMLHttpRequest, which understands HTTP, HTTPS, and HTTP-KeepAlive. This is the native implementation on the browser platforms and polyfilled in NodeJS via the dcp-xhr module. The polyfill includes deep network-layer debugging hooks.

init() and initSync() - CommonJS

From your NodeJS application (or any other using the CommonJS require function), you can invoke require('dcp-client').init() which initializes the dcp-client library. This function returns a promise that, once resolved, signals that the DCP modules have been injected into the NodeJS module memo (more about DCP modules below). Alternatively, you may call initSync with the same arguments and behavior as init except that the initialization is performed synchronously.

The init function takes zero or more arguments, allowing the developer to create an object which overrides the various DCP defaults; in particular, the location of the scheduler and the name of the code bundle which is executed to provide the APIs. This object has the same "shape" as the dcpConfig export from the library, and this is no coincidence: any parameter specified in the configuration will override the same-pathed property provided by the scheduler's configuration object that lives at etc/dcp-config.js relative to the scheduler's location.

Plain Object

A plain configuration object with the following properties is compatible with the DCP config.js library.

property pathmeaningdefault
scheduler.locationinstance of URL which describes the location of your scheduler.https://scheduler.distributed.computer/
autoUpdatetrue to download the latest version of the webpack bundle and use (eval) that code to implement
the protocol which accesses the scheduler, bank, etc. Otherwise, the bundle which shipped with the dcp-client npm package is used.
false
bundle.locationan instance of URL or a filename that describes the location of the code bundle, overriding whatever the default location.
String

If you pass a string to init, it will be treated as a filename; the contents of this file will be evaluated and the result will be used as the configuration object.

Note: filenames in this API are resolved relative to the calling module's location; all files are assumed to contain UTF-8 text.

Object which is an instance of URL

If the first argument object is an instance of URL, the URL will be treated as the location of the scheduler, the second parameter will be treated as the value of autoUpdate, and the third parameter will be treated as the value of bundle.location.

Local Defaults

In addition to application-specified options, users of NodeJS applications may add a local configuration file to override any baked-in defaults. This file is located in ~/.dcp/dcp-client/dcp-config.js, and should contain a JavaScript object literal in the UTF-8 character set.

Abbreviated Examples

/* Use the default scheduler */
await require('dcp-client').init();
let { compute } = require('dcp/compute');

/* Preferences are stored in my-dcp-config.js */
await require('dcp-client').init('my-dcp-config.js');
let { compute } = require('dcp/compute');

/* Use an alternate scheduler */
await require('dcp-client').init(URL('https://scheduler.distributed.computer'));
let { compute } = require('dcp/compute');

Additional Functionality

In addition to exporting the key APIs, when running dcp-client from NodeJS, the following modules are automatically injected into the NodeJS module memo, so that they can be used in require() statements:

ModuleDescription
dcp/computeThe Compute API
dcp/dcp-buildObject containing version information, etc. of the running bundle
dcp/dcp-cliProvides a standard set of DCP CLI options and related utility functions via yargs
dcp/dcp-eventsProvides classes related to cross-platform event emitting
dcp/dcp-configThe running configuration object (result of merging various options to init())
dcp/walletThe Wallet API
dcp/workerThe Worker API

Working with DCP-Client

General Use

Node - After calling init (see examples below), modules can be required using the module name that follows the initial dcp/.

await require('dcp-client').init();
const { EventEmitter } = require('dcp/dcp-events');

Web - After the dcp-client script tag is loaded (see examples below), modules are available as properties of a global dcp symbol.

const { EventEmitter } = dcp['dcp-events'];

examples/bravojs

The examples in this directory show how to use DCP from a web page using the BravoJS module system and no special web server. The usage is virtually identical to NodeJS, except that your web page must include a main module which is a SCRIPT tag with a module.declare declaration.

Abbreviated Examples
<SCRIPT src="/path/to/bravojs/bravo.js"></SCRIPT>
<SCRIPT src="/path/to/dcp-client/bravojs-shim.js"></SCRIPT>
<SCRIPT>
module.declare(["dcp-client/index"], function(require, exports, module) {
  /* Use the default scheduler */
  let { compute } = require('dcp-client').init()
  compute.for(....)
})
</SCRIPT>

examples/vanilla-web

The example in this directory shows how to use DCP from a web page with no module system at all. Configuration is performed by loading a dcp-config file from your preferred scheduler, overriding options in the global dcpConfig as needed, and then loading the dcp-client.js bundle, which immediately initializes the API. DCP libraries are exported via the global symbol dcp since there is no module system in this environment.

<!-- use an alternate scheduler -->
<SCRIPT id='dcp-client' src="/path/dcp-client/index.js" scheduler="https://myscheduler.com/"></SCRIPT>
const { compute } = dcp;
let job = compute.for(...);
job.on("ENOFUNDS", (fundsRequired) => {
  await job.escrow(fundsRequired);
  job.resume();
})

let results = await job.exec(compute.marketValue);
console.log(results);

Note For the first-dev release, terms like compute.marketValue and the value of DCC are not tied to anything. It's a placeholder for testing/experimental purposes. The MVP release will include an implementation of the costing and metering algorithms fundamental to tying DCC balance to actual work done.

Executing Jobs

At its core, a job can be thought of as an input set, a Work function; executing a job yields an output set.

Jobs (job handles) are generally created with the compute.for function, which is described in detail in the Compute API documentation. To execute the job, we invoke the exec() method of the job handle.

An input set can be described with arguments to compute.for() with RangeObject notation or passed directly as an enumerable object (such as an array or function* generator).

Examples

run Work on the whole numbers between 1 and 10:

job = compute.for(1, 10, Work)

run Work on the numbers 6, 9, 12, 15:

job = compute.for(6, 16, 3, Work)

run Work on the colors red, green, and blue:

job = compute.for(["red", "green" "blue"], Work)

Limitations to Consider

The Work function must be either a string or stringifyable via toString(). This means that native functions (i.e. Node functions written in C++) cannot be used for Work. Additionally, the function must be completely defined and not a closure, since stringification cannot take the closure environment into account. A rule of thumb is that if you cannot eval() it, you cannot distribute it.

Exposed APIs

The DCP Client bundle comes with a number of DCP APIs exposed for use in your own programs.

Compute API

Wallet API

Protocol API

  • provides a JavaScript interface to software developers and the Compute API which enables the transmission of data and work functions between
    • the scheduler and the worker
    • the scheduler and the bank
    • other entities as necessary
  • provides a JavaScript interface to software developers and other software components for the cryptographic operations needed by the protocol See https://docs.dcp.dev/specs/wallet-api.

Glossary

Entities

Scheduler

A NodeJS daemon which

  • receives work functions and data sets from Compute API
  • slices data into smaller sets
  • transmits work and data points to Worker
  • determines cost of work and instructs the Bank to distribute funds between entities accordingly
  • ensures that all tasks eventually complete, provided appropriate financial and computation resources can be deployed in furtherance of this goal
Bank

A NodeJS daemon which

  • manages a ledger for DCC which are not on the blockchain
  • enables the movement of DCC between entities requesting work and entities performing work
  • enables the movement of DCC between the ledger and the blockchain
  • enables the placement of DCC in escrow on behalf of the Scheduler for work which is anticipated to be done
Portal

A user-facing web application which allows or enables

  • creation and management of user accounts
  • management of bank accounts (ledgers)
  • transfer of DCC between bank accounts
  • transfer of DCC to and from the blockchain
  • execution of the browser-based Worker
Worker

A JavaScript program which includes a Supervisor and one or more Sandboxes

  • performs computations
  • retrieves work and data points from Scheduler
  • retrieves work dependencies from Package Server
  • returns results and cost metrics to Scheduler
  • Specific instances of Worker include
    • a browser-based Worker
    • a standalone Worker operating on Google's v8 engine
Sandbox

A component of a Worker used to execute arbitrary JavaScript code in a secure environment. Currently implemented by the DistributedWorker class (whose name will change someday). Generally speaking, we use one Sandbox per CPU core, although we might use more in order to work around system scheduler deficiencies, network overhead, etc. Sandboxes in the web browser are implemented using window.Worker().

Supervisor

The component of a Worker which communicates with the Scheduler and Sandboxen.

Concepts

Job

The collection consisting of an input set, Work Function, and result setup. Referred to in early versions of the Compute API (incorrectly) as a Generator.

Slice

A unit of work, represented as source code plus data and metadata, which has a single entry point and return type. Each Slice in a Job corresponds to exactly one element in the Job's input set.

Task

A unit of work which is composed of one or more slices, which can be executed by a single worker. Each Slice of each Task will be from the same Job.

Work or Work Function

A function that is executed once per Slice for a given Job, accepting the input datum and returning a result which is added to the result set.

Module

A unit of source code that can be used by, but addressed independently of, a Work Function. Compute API modules are similar to CommonJS modules.

Package

A group of related modules

Distributed Computer

A parallel supercomputer consisting of one or more schedulers and workers. When used as a proper noun, the distributed computer being discussed is the one hosted at https://portal.distributed.computer/

Bank Account

A ledger that acts as a repository for DCC which is not on the blockchain. The Bank can move DCC between Bank Accounts much more quickly than it can move DCC between Addresses on the Ethereum blockchain network. Metadata attached to bank accounts can restrict certain operations, such as ear-marking funds for use only by job deployment.

Address

A unique identifier in DCP that can be used as a Bank Account identifier (account number) or Address on the Ethereum network.

Wallet

In the general (blockchain) sense, a wallet is a piece of software that allows the user to interact with the greater economy as a whole. So as your actual wallet in your pocket has your cash and credit cards and you access your wallet in order to make a purchase and keep records (by pulling out cash or cards, and stuffing receipts back in), a blockchain wallet performs a similar function in that it gives you a place to store your private keys (your money), it provides a balance of what all those moneys add up to, it provides a way to receive moneys and send moneys, and provides a record of all those sends and receives. Most blockchain wallets provide at least 3 basic functions

  1. generate and stores your public/private key pairs
  2. allow you to use those key pairs through transactions (allows you to craft and transmit transactions to the peers)
  3. keep a record of the transactions

Additionally, most of the current crypto wallets (such as Bitcoin core) provide blockchain validation and consensus functions in that they can act to create or validate new blocks to the chain in addition to creating or validating transactions.

Distributed.Computer Wallet

The Distributed.Computer acts as a Wallet; the platform exposes Wallet-related functionality both via software APIs and the portal web site.

  • Public/private key pairs are generated via the portal, wallet API, and command-line utilities
  • Public/private key pairs are stored in the database as passphrase-protected Keystores
  • Public/private key pairs stored in the Distributed.Computer Wallet can be retrieved via the portal website
Keystore

A data structure that stores an encrypted key pair (address + private key). Generally speaking, the keystore will be encrypted with a passphrase.

Keystore File

A file that stores a JSON-encoded Keystore.

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Package last updated on 26 Aug 2020

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